package org.checkerframework.checker.index.lowerbound;

import com.sun.source.tree.BinaryTree;
import com.sun.source.tree.ExpressionTree;
import com.sun.source.tree.LiteralTree;
import com.sun.source.tree.MemberSelectTree;
import com.sun.source.tree.MethodInvocationTree;
import com.sun.source.tree.Tree;
import com.sun.source.tree.UnaryTree;
import java.lang.annotation.Annotation;
import java.util.Arrays;
import java.util.LinkedHashSet;
import java.util.Set;
import javax.lang.model.element.AnnotationMirror;
import javax.lang.model.element.Element;
import org.checkerframework.checker.index.BaseAnnotatedTypeFactoryForIndexChecker;
import org.checkerframework.checker.index.IndexMethodIdentifier;
import org.checkerframework.checker.index.inequality.LessThanAnnotatedTypeFactory;
import org.checkerframework.checker.index.inequality.LessThanChecker;
import org.checkerframework.checker.index.qual.GTENegativeOne;
import org.checkerframework.checker.index.qual.IndexFor;
import org.checkerframework.checker.index.qual.IndexOrHigh;
import org.checkerframework.checker.index.qual.IndexOrLow;
import org.checkerframework.checker.index.qual.LengthOf;
import org.checkerframework.checker.index.qual.LowerBoundBottom;
import org.checkerframework.checker.index.qual.LowerBoundUnknown;
import org.checkerframework.checker.index.qual.NegativeIndexFor;
import org.checkerframework.checker.index.qual.NonNegative;
import org.checkerframework.checker.index.qual.PolyIndex;
import org.checkerframework.checker.index.qual.PolyLowerBound;
import org.checkerframework.checker.index.qual.Positive;
import org.checkerframework.checker.index.qual.SubstringIndexFor;
import org.checkerframework.checker.index.searchindex.SearchIndexAnnotatedTypeFactory;
import org.checkerframework.checker.index.searchindex.SearchIndexChecker;
import org.checkerframework.checker.nullness.qual.Nullable;
import org.checkerframework.checker.signedness.qual.SignedPositive;
import org.checkerframework.checker.signedness.qual.SignednessGlb;
import org.checkerframework.common.basetype.BaseTypeChecker;
import org.checkerframework.common.value.ValueAnnotatedTypeFactory;
import org.checkerframework.common.value.ValueChecker;
import org.checkerframework.common.value.ValueCheckerUtils;
import org.checkerframework.common.value.qual.BottomVal;
import org.checkerframework.common.value.util.Range;
import org.checkerframework.dataflow.cfg.node.NumericalMultiplicationNode;
import org.checkerframework.framework.type.AnnotatedTypeFactory;
import org.checkerframework.framework.type.AnnotatedTypeMirror;
import org.checkerframework.framework.type.treeannotator.ListTreeAnnotator;
import org.checkerframework.framework.type.treeannotator.TreeAnnotator;
import org.checkerframework.javacutil.AnnotationBuilder;
import org.checkerframework.javacutil.TreeUtils;

/**
 * Implements the introduction rules for the Lower Bound Checker.
 *
 * <pre>
 *  The type hierarchy is:
 *
 *  Top = lbu ("Lower Bound Unknown")
 *   |
 *  gte-1 ("Greater than or equal to -1")
 *   |
 *  nn  ("NonNegative")
 *   |
 *  pos ("Positive")
 *  </pre>
 *
 * In general, check whether the constant Value Checker can determine the value of a variable; if it
 * can, use that; if not, use more specific rules based on expression type. This class implements
 * the following type rules:
 *
 * <ul>
 *   <li>1. If the value checker type for any expression is &ge; 1, refine that expression's type to
 *       positive.
 *   <li>2. If the value checker type for any expression is &ge; 0 and case 1 did not apply, then
 *       refine that expression's type to non-negative.
 *   <li>3. If the value checker type for any expression is &ge; -1 and cases 1 and 2 did not apply,
 *       then refine that expression's type to GTEN1.
 *   <li>4. A unary prefix decrement shifts the type "down" in the hierarchy (i.e. {@code --i} when
 *       {@code i} is non-negative implies that {@code i} will be GTEN1 afterwards). Should this be
 *       3 rules?
 *   <li>5. A unary prefix increment shifts the type "up" in the hierarchy (i.e. {@code ++i} when
 *       {@code i} is non-negative implies that {@code i} will be positive afterwards). Should this
 *       be 3 rules?
 *   <li>6. Unary negation on a NegativeIndexFor from the SearchIndex type system results in a
 *       non-negative.
 *   <li>7. The result of a call to Math.max is the GLB of its arguments.
 *   <li>8. If an array has a MinLen type &ge; 1 and its length is accessed, the length expression
 *       is positive.
 * </ul>
 */
public class LowerBoundAnnotatedTypeFactory extends BaseAnnotatedTypeFactoryForIndexChecker {

  /** The canonical @{@link GTENegativeOne} annotation. */
  public final AnnotationMirror GTEN1 = AnnotationBuilder.fromClass(elements, GTENegativeOne.class);

  /** The canonical @{@link NonNegative} annotation. */
  public final AnnotationMirror NN = AnnotationBuilder.fromClass(elements, NonNegative.class);

  /** The canonical @{@link Positive} annotation. */
  public final AnnotationMirror POS = AnnotationBuilder.fromClass(elements, Positive.class);

  /** The bottom annotation. */
  public final AnnotationMirror BOTTOM =
      AnnotationBuilder.fromClass(elements, LowerBoundBottom.class);

  /** The canonical @{@link LowerBoundUnknown} annotation. */
  public final AnnotationMirror UNKNOWN =
      AnnotationBuilder.fromClass(elements, LowerBoundUnknown.class);

  /** The canonical @{@link PolyLowerBound} annotation. */
  public final AnnotationMirror POLY = AnnotationBuilder.fromClass(elements, PolyLowerBound.class);

  /** Predicates about method calls. */
  private final IndexMethodIdentifier imf;

  /**
   * Create a new LowerBoundAnnotatedTypeFactory.
   *
   * @param checker the type-checker
   */
  @SuppressWarnings("this-escape")
  public LowerBoundAnnotatedTypeFactory(BaseTypeChecker checker) {
    super(checker);
    // Any annotations that are aliased to @NonNegative, @Positive, or @GTENegativeOne must also
    // be aliased in the constructor of ValueAnnotatedTypeFactory to the appropriate
    // @IntRangeFrom* annotation.
    addAliasedTypeAnnotation("javax.annotation.Nonnegative", NN);
    addAliasedTypeAnnotation(IndexFor.class, NN);
    addAliasedTypeAnnotation(IndexOrLow.class, GTEN1);
    addAliasedTypeAnnotation(IndexOrHigh.class, NN);
    addAliasedTypeAnnotation(LengthOf.class, NN);
    addAliasedTypeAnnotation(PolyIndex.class, POLY);
    addAliasedTypeAnnotation(SubstringIndexFor.class, GTEN1);

    addAliasedTypeAnnotation(SignedPositive.class, NN);
    addAliasedTypeAnnotation(SignednessGlb.class, NN);

    imf = new IndexMethodIdentifier(this);

    this.postInit();
  }

  @Override
  protected Set<Class<? extends Annotation>> createSupportedTypeQualifiers() {
    // Because the Index Checker is a subclass, the qualifiers have to be explicitly defined.
    return new LinkedHashSet<>(
        Arrays.asList(
            Positive.class,
            NonNegative.class,
            GTENegativeOne.class,
            LowerBoundUnknown.class,
            PolyLowerBound.class,
            LowerBoundBottom.class));
  }

  /**
   * Takes a value type (only interesting if it's an IntVal), and converts it to a lower bound type.
   * If the new lower bound type is more specific than type, convert type to that type.
   *
   * @param valueType the Value Checker type
   * @param type the current lower bound type of the expression being evaluated
   */
  private void addLowerBoundTypeFromValueType(
      AnnotatedTypeMirror valueType, AnnotatedTypeMirror type) {
    AnnotationMirror anm = getLowerBoundAnnotationFromValueType(valueType);
    if (!type.hasPrimaryAnnotationInHierarchy(UNKNOWN)) {
      if (!areSameByClass(anm, LowerBoundUnknown.class)) {
        type.addAnnotation(anm);
      }
      return;
    }
    if (typeHierarchy.isSubtypeShallowEffective(anm, type)) {
      type.replaceAnnotation(anm);
    }
  }

  /** Handles cases 1, 2, and 3. */
  @Override
  public void addComputedTypeAnnotations(Element element, AnnotatedTypeMirror type) {
    super.addComputedTypeAnnotations(element, type);
    if (element != null) {
      AnnotatedTypeMirror valueType = getValueAnnotatedTypeFactory().getAnnotatedType(element);
      addLowerBoundTypeFromValueType(valueType, type);
    }
  }

  /** Handles cases 1, 2, and 3. */
  @Override
  public void addComputedTypeAnnotations(Tree tree, AnnotatedTypeMirror type, boolean iUseFlow) {
    super.addComputedTypeAnnotations(tree, type, iUseFlow);
    // If dataflow shouldn't be used to compute this type, then do not use the result from
    // the Value Checker, because dataflow is used to compute that type.  (Without this,
    // "int i = 1; --i;" fails.)
    if (tree != null
        // Necessary to check that an ajava file isn't being parsed, because the call
        // to the Value Checker's getAnnotatedType() method can fail during parsing:
        // the check in GenericAnnotatedTypeFactory#addComputedTypeAnnotations only
        // checks if the **current** type factory is parsing, not whether the parent
        // checker's type factory is parsing.
        && !ajavaTypes.isParsing()
        && TreeUtils.isExpressionTree(tree)
        && (iUseFlow || tree instanceof LiteralTree)) {
      AnnotatedTypeMirror valueType = getValueAnnotatedTypeFactory().getAnnotatedType(tree);
      addLowerBoundTypeFromValueType(valueType, type);
    }
  }

  /** Returns the Value Checker's annotated type factory. */
  public ValueAnnotatedTypeFactory getValueAnnotatedTypeFactory() {
    return getTypeFactoryOfSubchecker(ValueChecker.class);
  }

  /** Returns the SearchIndexFor Checker's annotated type factory. */
  public SearchIndexAnnotatedTypeFactory getSearchIndexAnnotatedTypeFactory() {
    return getTypeFactoryOfSubchecker(SearchIndexChecker.class);
  }

  /** Returns the LessThan Checker's annotated type factory. */
  public LessThanAnnotatedTypeFactory getLessThanAnnotatedTypeFactory() {
    return getTypeFactoryOfSubchecker(LessThanChecker.class);
  }

  /** Returns the type in the lower bound hierarchy that a Value Checker type corresponds to. */
  private AnnotationMirror getLowerBoundAnnotationFromValueType(AnnotatedTypeMirror valueType) {
    Range possibleValues =
        ValueCheckerUtils.getPossibleValues(valueType, getValueAnnotatedTypeFactory());
    // possibleValues is null if the Value Checker does not have any estimate.
    if (possibleValues == null) {
      // possibleValues is null if there is no IntVal annotation on the type - such as
      // when there is a BottomVal annotation. In that case, give this the LBC's bottom type.
      if (containsSameByClass(valueType.getPrimaryAnnotations(), BottomVal.class)) {
        return BOTTOM;
      }
      return UNKNOWN;
    }
    // The annotation of the whole list is the min of the list.
    long lvalMin = possibleValues.from;
    // Turn it into an integer.
    int valMin = (int) Math.max(Math.min(Integer.MAX_VALUE, lvalMin), Integer.MIN_VALUE);
    return anmFromVal(valMin);
  }

  /** Determine the annotation that should be associated with a literal. */
  AnnotationMirror anmFromVal(long val) {
    if (val >= 1) {
      return POS;
    } else if (val >= 0) {
      return NN;
    } else if (val >= -1) {
      return GTEN1;
    } else {
      return UNKNOWN;
    }
  }

  @Override
  public TreeAnnotator createTreeAnnotator() {
    return new ListTreeAnnotator(new LowerBoundTreeAnnotator(this), super.createTreeAnnotator());
  }

  private class LowerBoundTreeAnnotator extends TreeAnnotator {
    public LowerBoundTreeAnnotator(AnnotatedTypeFactory annotatedTypeFactory) {
      super(annotatedTypeFactory);
    }

    /**
     * Sets typeDst to the immediate supertype of typeSrc, unless typeSrc is already Positive.
     * Implements the following transitions:
     *
     * <pre>
     *      pos &rarr; pos
     *      nn &rarr; pos
     *      gte-1 &rarr; nn
     *      lbu &rarr; lbu
     *  </pre>
     */
    private void promoteType(AnnotatedTypeMirror typeSrc, AnnotatedTypeMirror typeDst) {
      if (typeSrc.hasPrimaryAnnotation(POS)) {
        typeDst.replaceAnnotation(POS);
      } else if (typeSrc.hasPrimaryAnnotation(NN)) {
        typeDst.replaceAnnotation(POS);
      } else if (typeSrc.hasPrimaryAnnotation(GTEN1)) {
        typeDst.replaceAnnotation(NN);
      } else { // Only unknown is left.
        typeDst.replaceAnnotation(UNKNOWN);
      }
    }

    /**
     * Sets typeDst to the immediate subtype of typeSrc, unless typeSrc is already
     * LowerBoundUnknown. Implements the following transitions:
     *
     * <pre>
     *       pos &rarr; nn
     *       nn &rarr; gte-1
     *       gte-1, lbu &rarr; lbu
     *  </pre>
     */
    private void demoteType(AnnotatedTypeMirror typeSrc, AnnotatedTypeMirror typeDst) {
      if (typeSrc.hasPrimaryAnnotation(POS)) {
        typeDst.replaceAnnotation(NN);
      } else if (typeSrc.hasPrimaryAnnotation(NN)) {
        typeDst.replaceAnnotation(GTEN1);
      } else { // GTEN1 and UNKNOWN both become UNKNOWN.
        typeDst.replaceAnnotation(UNKNOWN);
      }
    }

    /** Call increment and decrement helper functions. Handles cases 4, 5 and 6. */
    @Override
    public Void visitUnary(UnaryTree tree, AnnotatedTypeMirror typeDst) {
      AnnotatedTypeMirror typeSrc = getAnnotatedType(tree.getExpression());
      switch (tree.getKind()) {
        case PREFIX_INCREMENT:
          promoteType(typeSrc, typeDst);
          break;
        case PREFIX_DECREMENT:
          demoteType(typeSrc, typeDst);
          break;
        case POSTFIX_INCREMENT:
        case POSTFIX_DECREMENT:
          // Do nothing. The CF should take care of these itself.
          break;
        case BITWISE_COMPLEMENT:
          handleBitWiseComplement(
              getSearchIndexAnnotatedTypeFactory().getAnnotatedType(tree.getExpression()), typeDst);
          break;
        default:
          break;
      }
      return super.visitUnary(tree, typeDst);
    }

    /**
     * Bitwise complement converts between {@code @NegativeIndexFor} and {@code @IndexOrHigh}. This
     * handles the lowerbound part of that type, so the result is converted to {@code @NonNegative}.
     *
     * @param searchIndexType the type of an expression in a bitwise complement. For instance, in
     *     {@code ~x}, this is the type of {@code x}.
     * @param typeDst the type of the entire bitwise complement expression. It is modified by this
     *     method.
     */
    private void handleBitWiseComplement(
        AnnotatedTypeMirror searchIndexType, AnnotatedTypeMirror typeDst) {
      if (containsSameByClass(searchIndexType.getPrimaryAnnotations(), NegativeIndexFor.class)) {
        typeDst.addAnnotation(NN);
      }
    }

    /** Special handling for Math.max. The return is the GLB of the arguments. Case 7. */
    @Override
    public Void visitMethodInvocation(MethodInvocationTree tree, AnnotatedTypeMirror type) {
      if (imf.isMathMax(tree)) {
        ExpressionTree left = tree.getArguments().get(0);
        ExpressionTree right = tree.getArguments().get(1);
        AnnotatedTypeMirror leftType = getAnnotatedType(left);
        AnnotatedTypeMirror rightType = getAnnotatedType(right);
        type.replaceAnnotation(
            qualHierarchy.greatestLowerBoundShallow(
                leftType.getPrimaryAnnotationInHierarchy(POS), leftType.getUnderlyingType(),
                rightType.getPrimaryAnnotationInHierarchy(POS), rightType.getUnderlyingType()));
      }
      return super.visitMethodInvocation(tree, type);
    }

    /**
     * For dealing with array length expressions. Looks for array length accesses specifically, then
     * dispatches to the MinLen checker to determine the length of the relevant array. If it's
     * found, use it to give the expression a type. Case 8.
     */
    @Override
    public Void visitMemberSelect(MemberSelectTree tree, AnnotatedTypeMirror type) {
      Integer minLen = getMinLenFromMemberSelectTree(tree);
      if (minLen != null) {
        type.replaceAnnotation(anmFromVal(minLen));
      }
      return super.visitMemberSelect(tree, type);
    }

    /**
     * Does not dispatch to binary operator helper methods. The Lower Bound Checker handles binary
     * operations via its transfer function.
     */
    @Override
    public Void visitBinary(BinaryTree tree, AnnotatedTypeMirror type) {
      type.addAnnotation(UNKNOWN);
      return super.visitBinary(tree, type);
    }
  }

  /**
   * Looks up the minlen of a member select tree. Returns null if the tree doesn't represent an
   * array's length field.
   */
  @Nullable Integer getMinLenFromMemberSelectTree(MemberSelectTree tree) {
    if (TreeUtils.isArrayLengthAccess(tree)) {
      return ValueCheckerUtils.getMinLenFromTree(tree, getValueAnnotatedTypeFactory());
    }
    return null;
  }

  /**
   * Looks up the minlen of a method invocation tree. Returns null if the tree doesn't represent an
   * string length method.
   */
  @Nullable Integer getMinLenFromMethodInvocationTree(MethodInvocationTree tree) {
    if (imf.isLengthOfMethodInvocation(tree)) {
      return ValueCheckerUtils.getMinLenFromTree(tree, getValueAnnotatedTypeFactory());
    }
    return null;
  }

  /**
   * Given a multiplication, return its type if the LBC special-cases it, or null otherwise.
   *
   * <p>The LBC special-cases {@code Math.random() * array.length} and {@code Random.nextDouble() *
   * array.length}.
   *
   * @param node a multiplication node that may need special casing
   * @return an AnnotationMirror representing the result if the special case is valid, or null if
   *     not
   */
  @Nullable AnnotationMirror checkForMathRandomSpecialCase(NumericalMultiplicationNode node) {
    AnnotationMirror forwardRes =
        checkForMathRandomSpecialCase(
            node.getLeftOperand().getTree(), node.getRightOperand().getTree());
    if (forwardRes != null) {
      return forwardRes;
    }
    AnnotationMirror backwardsRes =
        checkForMathRandomSpecialCase(
            node.getRightOperand().getTree(), node.getLeftOperand().getTree());
    if (backwardsRes != null) {
      return backwardsRes;
    }
    return null;
  }

  /**
   * Returns a non-null value if randTree is a call to Math.random() or Random.nextDouble(), and
   * arrLenTree is someArray.length.
   *
   * @param randTree a tree that might be a call to a {@code random} method
   * @param arrLenTree a tree that might be an array length access
   * @return a non-null value if randTree is a call to Math.random() or Random.nextDouble(), and
   *     arrLenTree is someArray.length
   */
  private @Nullable AnnotationMirror checkForMathRandomSpecialCase(Tree randTree, Tree arrLenTree) {
    if (randTree instanceof MethodInvocationTree && TreeUtils.isArrayLengthAccess(arrLenTree)) {
      MethodInvocationTree miTree = (MethodInvocationTree) randTree;

      if (imf.isMathRandom(miTree, processingEnv)) {
        // This is Math.random() * array.length, which must be NonNegative
        return NN;
      }

      if (imf.isRandomNextDouble(miTree, processingEnv)) {
        // This is Random.nextDouble() * array.length, which must be NonNegative
        return NN;
      }
    }
    return null;
  }

  /** Checks if the expression is non-negative, i.e. it has Positive on NonNegative annotation. */
  public boolean isNonNegative(Tree tree) {
    // TODO: consolidate with the isNonNegative method in LowerBoundTransfer
    AnnotatedTypeMirror treeType = getAnnotatedType(tree);
    return treeType.hasPrimaryAnnotation(NonNegative.class)
        || treeType.hasPrimaryAnnotation(Positive.class);
  }
}
